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College Park, MD 2013 PROCEEDINGS of the NPA 1
The point of unification in theoretical physics James E. Beichler
PO Box 624, Belpre, OH 45714
e-mail: jebco1st@aol.com
It would seem to many physicists that the unification of physics within a single paradigmatic theory has
been the primary goal in science for only the past few decades, but this would not be true. Unification was the
original goal of Einstein and a few other physicists from the 1920s to the 1960s, before quantum theorists began
to think in terms of unification. However, both approaches are basically flawed because they are individually
incomplete as they now stand. Had either side of the controversy just simplified their worldview and sought
commonality between the two, unification would have been accomplished long ago. The point is, literally, that
the discrete quantum, continuous relativity, basic physical geometry and classical physics all share one com-
mon characteristic – a paradoxical duality between a dimensionless point and an extended length in any di-
mension – and if the problem of unification is approached from an understanding of how this problem relates
to each paradigm all of physics could be unified under a single new theoretical paradigm.
1. Introduction
Every physical theory since the days of the ancient Greek phi-
losophers has fallen prey to the same problem: What is the dif-
ference between a point and an extension in space or time? Gen-
eral relativity describes matter and energy as a metric of curva-
ture, yet the theory falls apart at various singularities. Quantum
theorists debate whether particles are extended bodies or dimen-
sionless points. So both views are unique but suffer from similar
problems. The Standard Model of particles is based upon the
reality of point particles, as are the quantum loop and super-
string theories, but all such theories suffer from the same funda-
mental problem – how can dimensionless point particles be ex-
tended to account for the three-dimensional space?
On the other hand, there is as yet no theorem or method,
whether mathematical or physical, that can be used to generate
an extended space of any dimensions, let alone our common
three-dimensional space, from individual points. Yet it is gener-
ally understood in geometry that every continuous line contains
an infinite number of dimensionless points. Modern mathematics
contains many continuity theorems that prove this very fact. At
best, modern mathematicians have only partially overcome this
difficulty in calculus, the mathematics of change and motion, by
defining a derivative at a point as a limit rather than a reality.
The metric differential geometry of Riemann, upon which gen-
eral relativity is based, takes advantage of a similar mathematical
gimmick and only addresses the curvature of n-dimensional sur-
faces that approach zero dimension or extension without ever
reaching that limit. Even the Heisenberg uncertainty principle
falls victim to a variation of this same difficulty. The uncertain-
ties in position and time can never go to zero since the corre-
sponding uncertainties in momentum and energy will become
infinite. These similar difficulties define the central problem of
physics and unification.
Quantum theory, relativity theory and classical theories in
physics and mathematics are not so different when viewed with-
in this context as is generally thought. The evidence is clear; the
question of how points in physical space are able to form dimen-
sionally extended lines, surfaces or measurements must be dis-
covered before unification in physics can be completed. Both
relativity and the quantum theory work and they both work very
well as they are, so they are both equally fundamental and neces-
sary to any new unified theory. Neither theory is more funda-
mental than the other. Recognizing and accepting this equality is
the second step toward unification. Once the fact that both para-
digms are prone to the same problem in the concept of a point is
accepted, solving this problem will become the rallying point for
unification. That is the only possible point where unification can
occur in theoretical physics.
Toward that end, it will be shown that an extended geometry
can be constructed from individual dimensionless points under
special conditions. The resulting theorem in physical mathemat-
ics gives a great deal of insight into both the physical origins and
meaning of the quantum as well as its relationship to relative
space and time. The method used is actually implied in Rie-
mann’s [1] original 1854 development of the differential geome-
try of surfaces as well as elsewhere in physics and mathematics.
This theorem generates a three-dimensional space with exactly
the properties observed in our commonly experienced three-
dimensional space and could thus be considered a physical reali-
ty theorem.
2. The central problem of physics
2.1. Point mathematics
Calculus and other methods of calculation used in all of phys-
ics ultimately depend upon a rigorous mathematical definition of
instantaneous velocity or speed.
(1)
This definition depends on two fundamental ideas: (1) a moment
or instant of non-zero time must exist; and (2) space and time are
unbroken continuities that emerge from an infinite number of
connected dimensionless points. This notion differs from the
discrete in quantum theory in that space and time cannot be dis-
continuous although a quantum limit within the context of either
the uncertainty in momentum or the uncertainty in energy could
be approached. This situation creates a logical paradox that has
gone completely misinterpreted in science, where mathematics is
Beichler: The point of unification Vol. 10 2
accepted completely and wholly as applicable to physical situa-
tions without question or limitations. In other words, there seems
to be a gross conceptual divide between the mathematical system
of calculus and Heisenberg’s interpretation of reality. Otherwise,
quantum mechanics and other quantum models are considered
completely non-geometrical.
Space-time theories in general assume extension-geometries,
while general relativity is based on the concept of a metric exten-
sion in which the slope or the amount of curvature of space can
be determined as a small volume of three-dimensional space
shrinks and approaches the zero point limit.
(2)
Put another way, while both geometry and calculus use exten-
sions to explain the concept of a point or use an extension-based
geometry to explain space itself, no method or logical argument
by which points in space could generate extensions, let alone the
extension-based geometry necessary to represent the concepts of
space and time, exists. The closest method that exists in science is
the quantum method of perturbation which merely smears a
dimensionless point over an already existing three-dimensional
space. This quantum method gives rise to such misconceptions as
a fuzzy point, quantum foams and quantum fluctuations to ex-
plain the continuity of the lowest possible level of reality.
A mathematical method of generating an extended space or
time from points should have been developed long ago since the
inverse logical argument is a necessary requirement for mathe-
matical rigor in both geometry and arithmetic (calculus), but
such a method has never been developed. The problem has never
even been identified or discussed by mathematicians. This over-
sight creates a gaping hole in mathematical logic, to put it lightly,
especially in cases where it applies to physical realities such as
our commonly experienced three-dimensional space.
The solution to this problem would be to develop a mathe-
matical theorem that guarantees the physical reality of any given
space if that space can be generated from dimensionless points.
However, there remains a single barrier to doing so. To form a
continuous extension, two points must at least be contiguous, i.e.,
making contact or touching, but that would be impossible. So
the major obstacle to solving this problem is how to define conti-
nuity relative to contiguity. A conceptual definition of contigu-
ous dimensionless points must be established before continuity
can be assured. Yet two dimensionless points could never be
made contiguous by contact because contact would render them
‘overlapping’ or coincident simply because they are dimension-
less. However, there is a way to indirectly solve this abstract
mathematical paradox: Two independent dimensionless points
could only be considered contiguous without actually depending
on contact between them if and only if they were so close that no
other dimensionless point could be placed between them to sepa-
rate them. This situation is hard to imagine, but the concept is
mathematically and logically valid.
Take two dimensionless points, A and B, in close proximity to
each other. In order to generate a one-dimensional continuous
extension from them, these two points must find positions con-
tiguous to each other. But having no dimensions in themselves
for reference as to their relative positions to each other, this can-
not be accomplished. However, they are only restricted to being
dimensionless in the dimension(s) they share in real three-
dimensional space.
According to Gödel’s [2] theorem, all that can be proven with-
in a system is the internal consistency of that system. The validity
(truth) of that system can only be determined logically from out-
side of the system. So, all that present mathematics or physics
can determine – prove or verify in either case – is the logical con-
sistency of the system based upon their theorems and/or theories
of the three-dimensionality of space. A reality theorem in physi-
cal mathematics would therefore necessitate a higher four-
dimensional embedding space (manifold) to guarantee that the
three-dimensioned space could be generated from dimensionless
points. This very solution to the problem is implied in Riemann’s
original development of the concept of space curvature whereby
an n-dimensional space is embedded in an n+1-dimensional
manifold.
If perpendicular lines in the external embedding direction are
from both contiguous points A and B, these lines would normally
remain parallel and a distance AB apart in the embedding direc-
tion no matter how far they are extended. This does nothing to
verify the reality of the three-dimensional space.
However, if the three-dimensional space is internally curved in a
second dimension, then the lines drawn from the dimensionless
points would draw closer three-dimensionally the further they
are extended in the fourth direction. This method thus requires
the minimum of a two-dimensionally curved one-dimensional
line in a further embedding space (manifold) to distinguish reali-
ty. Once the extended lines in the embedding direction have
moved at least as far as the infinitesimal distance AB between
them they would meet.
The extensions in the fourth direction would then turn back to
the other side of the three-dimensional space and return to the
points from which they originated, maintaining and guarantee-
ing continuity of the dimensionless points in three-dimensional
space.
Another point C is contiguous to A and lies at the same infini-
tesimal distance from A, but in the opposite direction in three-
College Park, MD 2013 PROCEEDINGS of the NPA 3
dimensional space. Under the same procedure, C and A would
also coincide at one point in the embedding direction that is at
least equal to or greater than the infinitesimal distance between
them in three-dimensional space. In fact, A, B and C will all come
together at the same point in the embedding direction. If two
more points to either side of B and C are added – designated as D
and E – they would also coincide at the same point in the fourth
direction. Eventually an infinite number of points to either side
of B and C would converge and form a closed space in one of the
three-dimensions of three-dimensional space. All of these points
would coincide at the same point in the higher fourth dimension
of space.
When the same procedure is conducted for the other two di-
mensions of three-dimensional space, all points extended in the
fourth direction of space would coincide at a single point that is
at least as far from three-dimensional space as the sum of an infi-
nite number of infinitesimal distances that separate the infinite
number of points that make up the closed three-dimensional
space. The real three-dimensional space that is formed by this
logical procedure would be internally double polar spherical, but
the embedding higher-dimensional space would be single polar
spherical and at least as large as all of the dimensions in the real
closed three-dimensional space. This single polar structure has
important and previously unrecognized consequences for phys-
ics. This embedding space is exactly the type of physical hyper-
space proposed by William Kingdon Clifford [3] and envisioned
by other mathematicians in the late nineteenth century after they
had been introduced to Riemann’s generalized differential geom-
etry.
2.2. Point physics
This type of structure for the embedding space (Riemann’s
manifold concept) is clearly implied in the classical electromag-
netic concept of the magnetic vector potential. The vector poten-
tial is defined as B=del cross A, where B is the magnetic field
strength and A is the vector potential. The del function or opera-
tor is defined as
. (3)
As this equation indicates, the del function operates in all three
dimensions of space simultaneously, so its cross product with the
vector potential A yields the magnetic field B in three-
dimensional space. Therefore A must be perpendicular to all
three dimensions of normal spaces simultaneously and thus ex-
tended in the fourth dimension of space.
Electromagnetic theory describes two different types of fields,
the electric field E and the magnetic field B, that coexist but are
interdependent. Both fields are three-dimensional, but each is
directionally different in normal space. The E field interacts with
charged bodies radially toward a center point, but B interacts
with moving charges centripetally around the central point yield-
ing the combined force as described by the Lorentz equation:
. (4)
The cross product in the second term implies a four-dimensional
component as compared to the three-dimensional components of
the first term. The scalar E field is similar to the scalar gravita-
tional field in that they are both radially directed and can be ex-
pressed by metric or extension geometries. However, a metric
geometry cannot be used to describe the vector potential since
the second term is centripetally directed around a point center;
hence the force is derived from the cross product. Instead, a
point-based geometry is implied by magnetism.
The physical role of point geometries was first noted by Wil-
liam Kingdon Clifford [4,5] in the 1870s. Clifford [6] is better
known for ‘anticipating’ general relativity by stating that matter
is nothing but curved space and the motion of matter is nothing
but variations in that curvature. Yet when he developed his theo-
ry of matter, he did not use Riemannian geometry and he shied
away from gravity, instead working toward a theory of magnetic
induction based on an hyperspatial point geometry of his own
design using biquaternions. His biquaternions represented mag-
netic vector potentials extended in the fourth dimension of space.
Clifford’s theoretical work is all but forgotten today, but it did
influence the further development of geometry by Felix Klein [7],
who published his version of Clifford’s geometry after Clifford’s
early death, and Élie Cartan [8] who developed a point geometry
of spinors based on Clifford’s efforts and later developed [9] his
own physical unification model. Cartan’s geometry was then
used by Einstein [10] in his 1929 attempt to unify general relativi-
ty and electromagnetic theory, utilizing a concept called distant
parallelism.
A group of Russian scientists have since tried to revive the
1929 Einstein-Cartan geometric structure of space-time to de-
scribe a new form of gravity based on the concept of a torsion
field [11]. This concept is also related to the efforts of scientists to
develop a concept of gravitomagnetism based on an equation
first written by Oliver Heaviside [12] in 1893.
. (5)
Heaviside only came upon this formulation through an analogy
between electromagnetism and gravity rather than any new the-
oretical insights. All of these scientists have been unknowingly
trying to reinterpret gravity in terms of some form of combined
point/extension geometry, but they have missed the point of
unification by not placing their interpretation of these equations
in those terms.
3. Standard unification models
Modern quantum unification theories do not really try to uni-
fy gravity theory (either Newtonian or relativistic) and the quan-
tum in as much as they try to completely replace general relativi-
ty and classical physics. However, doing so would be impossible
since the quantum theory is incomplete with regard to gravity. It
simply ignores any possible effects of gravity at the quantum
level of reality. Therefore, unification on the basis of the quantum
would be more of an overthrow or coup d’état of the relativity
paradigm. This attitude is so deeply ingrained in the quantum
worldview that the large particle colliders designed to verify
certain aspects of the quantum theory do not take gravity into
account and their results should therefore be suspect. Quantum
Beichler: The point of unification Vol. 10 4
theorists just assume that the quantum theory will eventually
explain everything, but simply identifying the carrier particle of
gravity as a graviton and assuming it will eventually explain
gravity does absolutely nothing to explain gravity or unify the
quantum and relativity.
For his part, Einstein envisioned the four-dimensional space-
time continuum of our world as a unified field out of which both
gravity and electromagnetism emerged. He further hoped that
the quantum would emerge as an over-restriction of field condi-
tions. However, from the perspective of the fourth spatial dimen-
sion the four-dimensional expanse is filled with a single field of
potential that is the precursor to everything that exists in three-
dimensional space – gravity, electricity, magnetism, matter,
quantum, life, mind and consciousness. These physical things are
just different aspects of field interactions modified by the physi-
cal constants that describe the nature of the single unified field.
This worldview introduces a certain duality to our existence
that has already been discussed to some extent in science as
wave/particle duality. Its nature as an unsolvable but necessary
paradox has dominated the scientific debate for several decades.
Einstein, Bohr, Heisenberg, and Schrödinger as well as other sci-
entists have all fallen prey to the duality of worldviews, although
it is perhaps more accurate to say that they have been held pris-
oners by it. This duality, whether it is called yin and yang, male
and female, or certainty and uncertainty, is built into the very
fabric of space-time. In physical geometry, this duality takes the
form of the difference between a space made from dimensionless
points and one made from extensions.
The four mathematical conditions that yield a three-
dimensional space that is similar in characteristics to our normal-
ly experienced space are quite straightforward. The first two are
easily recognized: (1) a one-dimensional line extending in the
fourth direction from a dimensionless point in three-dimensional
space (Kaluza’s A-line) must form a closed loop; and (2) all such
lines must be of equal length. These are the same mathematical
conditions that Theodor Kaluza [13] placed on his five-
dimensional extension of general relativity in 1921. Oskar Klein
adopted the Einstein-Kaluza structure in 1926 [14] in the first of
his several attempts to quantize general relativity. The subse-
quent Kaluza-Klein physical model of space-time was adopted
and expanded by the superstring theorists in the 1980s. Conse-
quently, all such physical models of space-time suffer from the
fact that they are incomplete without considering the other two
conditions describing the higher embedding dimension.
The third and fourth conditions are not so readily recognized,
at least not for the last century. These ideas were popular in the
late nineteenth century when scientists first searched for curved
space in the distant stars. Otherwise, the conditions are straight
forward: (3) The lines extending into the higher dimension must
be at least as long as the longest possible circumference line en-
circling three-dimensional space; and (4) All such lines must
pass through a single common point or pole. This means that the
fourth dimension of space must be macroscopically extended,
just as Einstein and his colleagues [15, 16] proved in the 1930s,
while the fourth dimension must have the geometry of a single-
polar closed Riemannian surface. Each of the one-dimensional
lines extended in the fourth direction of space (Kaluza’s A-lines)
would work like a Möbius strip in that each and every point in
three-dimensional space would have an inherent half-twist to it,
without which rotational motions would be impossible in three-
dimensional space. This idea is presently unknown in either sci-
ence or mathematics.
Clifford envisioned this same structure for four-dimensional
space in the 1870s, but the physical consequences imposed by
these necessary conditions are far more important to modern
physics. They rule out the possibility that the superstring theories
which depend on infinitesimally small and compactified higher
dimensions could possibly represent physical reality. All such
physical theories and models, including the Standard Quantum
Model of particles, are no more than highly accurate approxima-
tion methods that do not really portray material reality as it is
because they cannot offer any rationale or method for the emer-
gence of three-dimensional space from the dimensionless point-
particles that they theorize. All quantum field theories suffer
from this same problem.
The half-twist associated with each point of our real three-
dimensional space means that rotations of extended lines around
a central point are possible. In other words, three-dimensional
space can be characterized by its support of either translational
or rotational motions, which just happens to be observationally
and experimentally true. Furthermore, the characteristic twist in
each point easily accounts for the half-spin of elementary materi-
al particles and, in fact, establishes a requirement that all real
material particles must have half-spins. Only protons, neutrons,
electrons (muons and tauons) and neutrinos are real material
particles, meaning, of course, that all of the geometrical points
within the space they occupy are constrained by the half-spin,
i.e., the point-lines extending into the fourth dimension are bun-
dled together by the same half-spin. All other hypothetical parti-
cles are artificial constructions and temporary intermediate ener-
gy states characterized by spins of 0 and 1. In a strict philosophi-
cal and mathematical sense, all points in three-dimensional space
correspond to each other and co-exist with one another since all
points in three-dimensional space pass through the same single
pole in the higher dimension. They all become one at the single
pole. This single simple fact is more than sufficient to explain
quantum entanglement.
Einstein’s [17] original gravity theory utilized a double polar
Riemannian sphere to model gravity as four-dimensional space-
time curvature, but he only considered curvature an internal or
intrinsic property of the four-dimensional space-time continuum.
In this case, Einstein’s positivistic leanings just got the better of
him because he could have instead interpreted the curvature as
extrinsic and thus requiring a fourth dimension of space without
changing the mathematical model. Unfortunately, positivism was
the dominant philosophical force in the earlier interpretations of
both general relativity and the quantum theory. In both cases,
positivism rendered both theories incomplete, misled advancing
science and still does so. Furthermore, the Riemannian geometry
that Einstein used is only a metric or extension-based geometry,
which cannot possibly account for the physics of the individual
points in space. Since classical electromagnetic theory implies the
corresponding existence of both extension and point-based geo-
metrical structures, all of his attempts to unify gravity and elec-
tromagnetism were incomplete from the start. But then Newtoni-
College Park, MD 2013 PROCEEDINGS of the NPA 5
an gravity only necessitates an extension-geometry, which also
misled Einstein’s unification attempts.
This difficulty, however, does not mean that the task of unifi-
cation is impossible. Quite the contrary. Einstein was on the right
track when he adopted Kaluza’s five-dimensional space-time
framework in the late 1930s as well as when he adopted Cartan
geometry in 1929 and the symmetric/anti-symmetric tensor cal-
culus [18,19] after 1945. All of these geometric systems offer a
limited form of a combined point- and extension-geometric struc-
ture. But Einstein failed to realize two potential solutions. The
first was that a combination of these two geometries through a
Kaluza five-dimensional structure could lead to a single field
theory. Secondly, Einstein never fully realized that the quantum
could not possibly emerge naturally from an over-restriction of
the mathematics as he hoped because the quantum is itself a fun-
damental and necessary property of the space-time continuum.
Einstein’s model relied upon the fact and truth of a connection
between space and time to form space-time, so the quantum,
which can only be seen or accessed when changes in space and
time are considered independent of one another, could never
have emerged in Einstein’s mathematical researches. Planck’s
constant is the binding constant for space and time
Put another way, the quantum is all about function (physical
processes) and relativity is all about structure (form). Together
they form a duality in which certain areas of physical reality
overlap, but neither one can completely replace the other within
our commonly experienced four-dimensional space-time contin-
uum. Both are necessary to work together, but they can work
independently under the proper conditions. For their part, mod-
ern quantum theorists do no better because they dismiss geome-
try altogether and in so doing they develop and rely on incom-
plete pictures of quantized processes. Function cannot exist
without form. So they develop statistical excuses as a substitute
or alternate mapping system to mistakenly replace the geometric
structure of space-time. Statistical methods merely smudge out
the dimensionless points of space and time into surfaces to estab-
lish an alternate mapping of space and time and thus mathemati-
cally mimic true geometric extensions.
Proponents on both sides of the debate – quantum theorists
and relativists – need simply look at reality and analyze what
they are doing in a serious critical manner to find the theoretical
keys to unification. Then, and only then, will the method of uni-
fication become obvious. In reality there is no fundamental dif-
ference between the physics of Newton, Einstein, Bohr, Heisen-
berg, DeBroglie or Schrödinger that cannot be overcome. When
the central problem is successfully identified, there is no real
need for inventing artificial mathematical and physical gimmicks
such as virtual particles, particles whose existence can never be
verified, strings, superstrings, branes and many more dimen-
sions of space than are necessary. Scientists have failed to realize
why the difference between the quantum and relativity exists
and have therefore missed the only solution of how to unify
them.
4. The quantized space-time continuum
Physicists need to ask ‘what is the quantum and how, exactly,
does Planck’s constant fit into our commonly experienced mate-
rial world?’ In spite of all the grandiose successes of the quantum
theory, many of the top theorists have admitted that they have
no idea what the quantum is or what it all means. Without these
last pieces of the puzzle, these questions cannot be adequately
answered and unification cannot proceed any further than the
past dismal failures of scientists.
The real conceptual discrepancy derives from the simple fact
that the uncertainties in momentum and energy, as expressed in
the Heisenberg uncertainty principle, are in themselves com-
pletely and totally fundamental physical quantities that need not
be further reduced into more fundamental quantities such as
mass, speed and time. The fundamental nature of momentum
and energy are implied by the conservation laws of momentum
and energy. Heisenberg’s uncertainty principle can only work its
mathematical magic if the momentum and the energy are truly
fundamental, even more so than space and time, such that they
represent a simple concept of physical ‘change’ without direct
reference to corresponding quantities of space, time and mass.
So, ‘is it possible to change position, represented by the un-
certainty in position (spatial change), and momentum while there
is no corresponding change in time?’ This question is physically
nonsensical yet it is directly implied by the Heisenberg uncer-
tainty principle. Moreover, this notion is the root of Einstein and
others’ declarations that quantum mechanics is incomplete. If
momentum and energy are not fundamentally unique and inde-
pendent quantities, then the Heisenberg uncertainty principle is
not fundamental enough to determine either material or physical
reality without reference to ‘hidden variables’.
From the perspective of the macroscopic world, it is quite ev-
ident that the momentum and energy of moving material objects
have real values at every infinitesimal point location along their
path through space. Mathematical proofs of continuity guarantee
the unbroken continuity of physical reality. However, quantum
theorists claim that continuity is not necessarily true on the quan-
tum level of reality where the ‘discrete’ quantum rules. The
quantum notion of ‘uncertainty’ in position, time, momentum
and energy, by design, represents a mathematically ideal (alt-
hough not necessarily an actual or even practical) isolated or
‘discrete’ event that occurs completely independent of past and
future events at an individual unconnected point in space. In
other words, there is no reason, whether scientific or mathemati-
cal, to conclude with anything approaching any certainty that
momentum and energy are completely fundamental quantities at
the subatomic realm of physical reality (as are space, time and
mass) other than a faith in their a priori assumption by quantum
scientists and philosophers that they are.
This point of contention between the classical and quantum
worldviews can be better illustrated by a comparison between
space-time and the dimensionless point or ‘moment’ of time that
lies at the origin in a space-time diagram. The origin of the axes
corresponds to a discrete quantum point ‘event’ which occurs at
a particular location in three-dimensional space. On the other
hand, the coexistence of relative time and relative space only
implies the existence of a ‘point’ in space-time where their axes
meet. This point would be the same point that is theorized in the
mathematics of calculus when the limit of the time interval grows
small enough that it approaches zero time during the measure-
ment of an instantaneous velocity or speed.
Beichler: The point of unification Vol. 10 6
However, recognizing the existence of that point alone is in-
sufficient to explain either the physical importance or the signifi-
cance of that point.
The time and space axes inside the ‘unit of change’ are essentially
absolute because they refer only to the ideal geometrical point
center. If momentum and energy are completely fundamental,
then reality must be limited to an indistinct extension of space
and time surrounding the origin of the axes. Hence there is a
‘zone’ of misunderstanding and contention surrounding the
point origin of the space-time axis, which can be called the fun-
damental or quantum ‘unit of change’. Different paradigms in-
terpret the ‘zone’ bounded by the basic ‘unit of change’ different-
ly, hence the fundamental problems and discrepancies between
the quantum, relativistic and Newtonian worldviews and therein
lays the central problem of physics.
4.1. The misconception of indeterminism
At this point in the analysis, quantum physicists and philoso-
phers would normally invoke concepts of indeterminism and
argue that the whole of the universe is inherently indeterministic.
Yet both indeterminism and determinism are false concepts and
have no place in real science. Even though quantum events may
correspond to individual dimensionless points in space which
can be defined at the origin of the space-time axis while all of
geometry is derived from dimensionless points, there is no rea-
son to automatically conclude that each and every point in space
simultaneously represents a quantum event. Discrete quantum
events are completely unconnected to other discrete quantum
events by definition. However, changing from the dimensionless
existence of a point at the center of the ‘fuzzy zone’ to a dimen-
sioned existence relative to the whole universe poses a problem
when the quantum event becomes a four-dimensional space-time
reality by collapse of the wave function. Put another way, the
dimensionless point at the location where the space and time
axes come together – the independent idealized space-time ‘now’
of the observed event – can occupy only one of an infinite num-
ber of possible locations or orthogonal directions (thus the ↕↔
symbols used in the diagram) corresponding to the x, y, z, and t
axes of normal space-time.
The idealized point ‘event’ must conform to the already es-
tablished direction of relative time because time goes on, or
moves forward, external to the ‘fuzzy zone’ surrounding the
‘event’ once it has been observed (or measured) by something
external to the ‘fuzzy zone’, i.e., the observer. When the time-axis
of the single quantum event collapses from all of its infinite
number of possible orientations around the central point in the
‘fuzzy zone’ and aligns with the flow of time surrounding it, its
spatial axes automatically align with the external spatial direc-
tions x, y, and z that define the common external three-
dimensional space. Only then does the event conform to the rules
and restrictions on reality established by the universe as a whole
and thus become a relativized physical reality.
This model is not entirely unique. A very important prece-
dent exists for this particular interpretation of the quantum par-
adox in the concept of a Hilbert space of infinite dimensions.
Each unique point-located event establishes its own independent
relative space-time framework, but there are an infinite number
of point-locations in this singular universe created by the event
and all are pegged to their own central event point at the origin
of the space-time axis. So the problem of ‘uncertainty’ inside the
‘fuzzy zone’ bounded by the ‘unit of change’ reduces to the sin-
gling out of one of the infinite number of possible axes orienta-
tions rather than a ‘collapse of the wave function’ that extends
throughout all of space. This alignment establishes the event’s
‘reality’ in the normal space-time continuum. If a wave explana-
tion still seems necessary, then it may be easier to think of the
collapsing wave function as representing a longitudinal wave
shrinking or ‘collapsing’ along a line in the fourth direction of
space rather than a transverse probability wave extended over
the whole of three-dimensional space while still centered on one
individual point in the space-time continuum.
The quantum point structure of an infinite-dimensional
space-time first suggested by Hilbert [20] is intimately related to
the mathematical concept of a Hilbert Space. (See for example
Brody and Hughston [21]) Hilbert space is a purely mathematical
projective space of rays that is non-linear with curves and de-
scribed by Riemannian metrics. A precedent for this interpreta-
tion already exists in general relativity and Hilbert’s work is also
reminiscent of Clifford’s earlier work on hyperspaces. Hilbert
[22] used such a construction to develop his own general relativ-
istic structure of space-time at about the same time that Einstein
initially developed general relativity. Einstein noted Hilbert’s
contribution for developing an alternate derivation of his theory
while Hilbert gave full credit for the discovery of general relativi-
ty to Einstein.
The probability of an infinite number of possible orientations
of space-time axes spinning around randomly within the ‘unit of
change’ or fuzzy point before collapsing into a singular unique
alignment with the normal ongoing passage of time axis is far
more realistic than the alternative quantum explanation of the
pre-collapse wave packet spread across the whole of the universe
as a probability cloud. Yet this picture limits the indeterminate
nature of the quantum to inside the ‘unit of change’. Logically
speaking, all of the probability is thus wound up inside the
‘fuzzy zone’ and the universe is still left deterministic outside of
the ‘fuzzy zone’, at least until the collapse of the wave packet
brings the event into alignment with external deterministic reali-
ty as well as Newtonian physics.
Thus we have a simple interpretation of quantum theory that
corresponds well to the model of reality posed by both special
College Park, MD 2013 PROCEEDINGS of the NPA 7
and general relativity. Both the indeterminism of the quantum
inside the ‘fuzzy zone’ and the determinism of relativity outside
of the ‘fuzzy zone’ coexist to create physical reality. The width of
the ‘fuzzy zone’ in both space and time is defined by the quan-
tum, so the quantum is and can be nothing other the smallest
possible measurement that yields a physically real event accord-
ing to the rules of our universe as expressed by physics.
In the end, scientists ‘create’ the uncertainty that they normal-
ly attribute to the whole of nature by their attempts to mimic
ideal mathematical abstractions on the stage of physical reality.
We are truly creating our own abstract reality by experiment, but
it is not and cannot be the reality of our external world. The
smaller we make the ‘unit of change’ size limit, either by abstrac-
tion or experimental measurement, approaching the zero point,
the greater the radical ‘change’ of orientation of the event point’s
axes, the harder it becomes to align the time axis of the point to
the external passage of time and thus the external space-time
geometry. This creates a greater uncertainty in the ‘quantum
measurement’ and, in fact, is the source of the measurement
problem in quantum theory. The very notion that the universe as
a whole is indeterministic is based on false logic as is determin-
ism.
4.2. Hidden variables and Planck’s constant
The situation described is reminiscent of a moving particle
that is confined to bounce around inside an ideal box (closed
surface) that is decreasing in size and volume. Although its ener-
gy remains constant, the particle’s motion grows increasingly
more erratic and random as the box’s volume decreases because
the particle bounces off of the interior wall of the box more and
more often as the box shrinks. Both the erratic motion of the par-
ticle and the shrinking size of the box can be equated to the ‘basic
unit of change’. It is normal to associate Planck’s constant with
both, depending on the circumstances, but in reality Planck’s
constant is related only to the size of the box and not the erratic
nature of the motion which is only indirectly proportional.
Meanwhile, the uncertainty of position at any given point of
space in the box is tied to the erratic motion of the particle, not
the shrinking size of the box. As the volume of space in which the
particle is confined during measurement (which yields the uncer-
tainty in the position) approaches the outer surface of the parti-
cle, the randomness of the motion of the particle increases expo-
nentially until the box surface (technically a measuring device)
coincides with the outer surface of the particle and its motion
(momentum) ceases altogether. This marks the ‘collapse of the
wave function’.
On the other hand, the energy density of the particle, with
constant kinetic energy over a decreasing volume of the box, in-
creases as the box shrinks. Mathematicians could abstract this
situation and say the energy density approaches infinity (zero
point energy) as the box’s volume goes to zero. But the volume of
the box can never go to zero; the volume of the box can only
grow as small as the particle size at which time the radical mo-
tion of the particle must go to zero because there would be no
room in the box for the particle to bounce around. Instead the
uncertainty tied to the erratic motion would go to zero as the box
stopped shrinking at the point of ‘collapse’, rather than when the
box’s size shrinks to zero. At this juncture, mathematics and
physics begin to part ways. According to physics, the box would
assume the shape of the particle (a fixed but non-zero point loca-
tion in space) as momentum goes to zero and the energy in the
erratic motion would be converted.
Clearly the mathematics and physics of the situation do not
match each other. In fact, the mathematics yields physically im-
possible answers. The same is true for the mathematical formal-
isms of quantum mechanics, which is the main source for prob-
lems and discrepancies between the quantum theory and other
physics paradigms. The uncertainty in position may have gone to
zero to define the measurement event, but the point location in
space never went to zero. The corresponding randomness in mo-
tion (uncertainty in momentum) went to a maximum value, but
when the measuring container closed in on the particle the mo-
mentum must have gone to zero as energy was apparently, but
not necessarily, lost to or absorbed by the container. In this case,
the center point of the particle would correspond to the axis of
the space-time diagram describing the event.
Before this moment, the motion of the particle was only
known by the uncertainties in position and momentum, but at
the moment of ‘collapse’ (energy exchange) the uncertainties in
energy and time were automatically invoked. At that moment,
the two different forms of the uncertainty principle became
equated, eliminating any reference to Planck’s constant. The un-
certainty relationship reduces to
(6)
which simplifies to become
. (7)
Given this last relationship, both the equations of special relativi-
ty and Newton’s second law of motion can be derived [23] by
noting how the uncertainties involved change relative to one
another. In other words, when the moment of measurement oc-
curs, a ‘collapse’ of uncertainty reestablishes the relationship
between the quantum event and the relative space-time continu-
um, as designated by the space-time diagram, and the quantum
situation reduces to a problem in normal classical physics.
There had been ‘hidden variables’ in the quantum uncertainty
relationships all along. They were always in the background, but
never invoked by the Heisenberg uncertainty principle until the
moment of collapse. There was never any accounting for time
(position in time) in the relationship between the uncertainties in
position and momentum before the ‘collapse’, nor would there
have been any accounting for position (spatial location) if the
uncertainty relationship between energy and time had been ap-
plied to the problem instead. Time and space, respectively, are
the ‘hidden variables’ in the Heisenberg uncertainty principle,
yet there is also an unsuspected ‘hidden variable’ in the classical
view of space-time, and that is Planck’s constant. When space
and time are reunited as space-time, Planck’s constant is sub-
dued, so Planck’s constant, which does not normally appear in
either Newtonian or relativistic physics, must always be hidden
in the background of classical physics as the binding constant for
space and time. Quantum uncertainty only comes from the scien-
Beichler: The point of unification Vol. 10 8
tific attempt to artificially separate space and time in the meas-
urement process.
When the quantum event – a measurement, observation or
other material interaction – occurs at a specific moment in time,
the uncertainty would lie along the vertical axis of the space-time
diagram invoking the application of ΔEΔt≥h and position in
space is ignored. When it occurs at a point in space along the
horizontal axis it would invoke the relationship ΔxΔp≥h. Togeth-
er, these would create the ‘sphere’ or ‘fuzzy zone’ of uncertainty
surrounding the zero point of the space-time diagram represent-
ing the mathematically idealized (rigorized) quantum event. This
‘fuzzy zone’ of uncertainty would amount to what some have
called a ‘fuzzy point’ and others call ‘quantum fluctuation’.
Quantum foams and other such explanatory gimmicks are no
more than quantized visualizations of Newton’s absolute space
or Einstein’s continuum with the slight addition of possible ran-
dom quantum fluctuations at different points in absolute space.
The ‘fuzzy zone’ is spread out over a greater but shrinking vol-
ume of space until the measurement is completed, at which time
the density of the ‘fuzziness’ goes to a maximum value and
Planck’s constant is invoked.
In reality, quantum theory is only supposed to deal with un-
related and physically unconnected events (unless entanglement
can be taken into account), so the empty space and time between
different independent events cannot be characterized by any one
individual event. The only possible justification for doing so
would be the probabilistic nature of quantum mechanics and the
corresponding spread of the wave function over space prior to
the moment when the wave function collapses to the single point
at the origin of the space-time diagram to create ‘reality’, as
quantum theorists would say. However, the mathematical model
of a wave that corresponds to a particle that is somehow spread
like warm butter over the whole universe is nothing more than a
prosthetic gimmick and red herring. Mathematical possibilities
such as those represented by the wave function do not necessari-
ly represent physical realities before the wave collapses.
The shrinking box or surface is not that bad an analogy, nor is
it unprecedented. An imaginary closed surface surrounding a
real object would normally be called a Gaussian surface in math-
ematics. It is a useful and often used analytical tool in physics.
When the ideas and analogies of the shrinking box are applied to
nature a new and startling result emerges – The shrinking box
analogy provides a realistic description of how the Schrödinger
wave function collapses to form an extended material particle
during a quantum interaction event or alternately how the quan-
tum energy of a light wave is absorbed as a photon, while the
erratic process of axes alignment inside the box (unit of change)
describes a corresponding purely quantum mechanistic and
indeterministic view of the event.
In the real world, this limit – the quantum limit – could be
used to explain the creation of either a pseudo-particle or a real
particle. The energy density in the box would either convert to a
momentary semi-stable field resonance or become a real particle
as the quantum limit (basic unit of change) of the box is reached.
Which case occurs depends on the extent to which the particular
situation conformed to the geometrical restrictions of reality, i.e.,
real particles must have half-spin. If the limit is approached in
such a manner that uncertainty inside the ‘fuzzy zone’ collapsed
and the resulting quantity conformed to the completely to the
geometric restrictions of space then a real particle such as an elec-
tron or positron would emerge from the process. Otherwise a
momentary ‘energy resonance’ (such as a Higgs boson) would
emerge or be created, but it would almost instantaneously dete-
riorate into some other form of energy or a real particle (parti-
cles) with energy because it does not meet the minimum physical
(geometrical) requirements of the universe for reality, i.e., half-
spin. This is exactly what occurs in high energy physics experi-
ments such as those conducted at the Large Hadron Collider at
CERN.
5. Single Field Theory
The resulting theoretical structure is called ‘single field theo-
ry’ or just SOFT. The term ‘single’ is used instead of ‘unified’
because Einstein’s less comprehensive attempts envisioned the
field as a unification of other common fields whereas other fields
are actually specialized structures within the single field. In any
case, the quantum can now be incorporated into this model quite
easily. First of all we have the new relationship between classical
electromagnetism and modified Newtonian gravity.
In both the Lorentz equation for electromagnetism and the corre-
sponding gravity equation the first terms represent three-
dimensional scalar potential fields while the second terms repre-
sent three-dimensional contributions to force by four-
dimensional vector potential fields.
Like magnetism, the new additional gravitational force acts
centripetally around a central mass. The velocity (v) represents
the orbital speed due to the central mass. The new variable Γ
represents the gravitational influence of all other (non-local) ma-
terial bodies in the universe on the local action. In essence, Γ rep-
resents the overall or global curvature of the universe, so the
cross product between Γ and the orbital momentum yields the
higher rotational speeds of stars and star systems orbiting galac-
tic cores. This effect would influence all orbital speeds around
any central material bodies and thus accounts for the small speed
increases NASA has detected in artificial satellites that slingshot
around planets and the sun. It would also account for the slightly
higher than expected speeds of the Voyager satellites that are
College Park, MD 2013 PROCEEDINGS of the NPA 9
presently exiting the solar system. This model also yields other
testable predictions [24,25], but this venue is too short to list them
all.
Like electromagnetism, a secondary equation relates the
quantity Γ to a new gravitational vector potential.
(8)
The gravitational vector potential I is the source of Dark Energy,
thus Dark Matter and Dark Energy are directly related. But the I
also stand as for inertia. Inertia is a point property of material
bodies as opposed to the gravitational inertia which is a metric
property of the curvature. The total mass inertia of a body is the
collective property of all the points within the body that fit under
the spatial curvature representing gravitational mass. Thus we
have a new equivalence principle that goes beyond that used in
general relativity.
The concept of point inertia also explains the source of the
Higgs boson in the Standard Model of particles. The Higgs boson
is not an exchange particle since the idea of particle exchange to
create the mass of a moving body is just a mathematical gimmick
(or artifact) that corresponds to individual inertial points under
the metric curvature of space and the Higgs field is none other
than the space-time continuum of general relativity. However,
outside of the boundaries of an extended material particle the
very points of space under the curvature Γ are points of Dark
Energy. So Dark Energy is no more than gravitational vector po-
tential in open space.
After the cross product is completed, the second gravitational
term would take the form
. (9)
The vector v4 is a velocity in the fourth direction of space whose
three-dimensional projection yields the true three-dimensional
orbit speed of a material body. However, writing the term in this
fashion opens other possibilities, primarily the momentum can
now be related to a DeBroglie matter wave, yielding
. (10)
The DeBroglie matter wave forms the basis of Schrödinger’s
wave mechanics, so gravity in the form of this modified Newto-
nian equation has now been quantized. Given the fact that elec-
trons orbiting atomic nuclei in each of the principle quantum
orbits form whole numbers of DeBroglie matter waves, the elec-
tronic shells in atoms can now be explained utilizing space-time
curvature. Incoming light waves with specific magnetic vector
potentials A can be absorbed by electron’s whose own magnetic
vector potential A just matches them for the proper quantum
leap to other orbits.
This formulation also indicates that the DeBroglie matter
wave extends in the fourth direction of space as a longitudinal
wave and is thus equivalent to the modified Newton model of
space as well as the Einstein-Kaluza five-dimensional model of
space-time. These findings indicate that the quantum forces a
limit to measurement that is restricted to the fourth dimension of
space as it affects how our normal three-dimensional space
evolves in time. In other words, Planck’s constant is a coupling
constant for four-dimensional space and time that manifests in
both conscious acts of measurement and non-conscious physical
interactions (entanglements) in three-dimensional space.
Since continuity is a physical property of both space and time,
the fundamental interaction between the single field and space-
time would be limited by an ‘effective width’ of three-
dimensional space in the fourth direction of the embedding
space. The ‘effective width’ of space would be characterized by
Planck’s constant or rather proportional to the fine structure con-
stant (α = e2/4πε0ħc) which would further consolidate electro-
magnetic theory into the model as well as electromagnetism into
the fundamental structure of space-time. The lowest energy state,
corresponding to the principle quantum number of n = 1, of the
three-dimensional universe would be equivalent to the primary
‘sheet’ surface with this ‘effective width’. Each succeeding ‘sheet’
would be stacked on top of the other (giving continuity) in the
fourth direction of space, corresponding to succeeding quantum
numbers.
Einstein’s original formulation of general relativity in terms of
tensors representing the curvature of space time yielded a simple
equation of the form
. (11)
The tensor Γ represents the space-time curvature while the ener-
gy-stress tensor T represents local matter associated with the
curvature. It is commonly understood that this equation says
matter curves space-time and the space-time curvature moves
matter. However, this equation cannot account for Dark Matter
and Dark Energy because it only represents the metric geometry
implied by the original form of Newton’s gravitational equation
F=mg. The new term extending Newtonian gravity to include
point geometry must also be represented.
The second term becomes the Newtonian equivalent of what is
called lambda CDM in the later version of Einstein’s tensor equa-
tion. It is now being used successfully to explain the Cold Dark
Matter surrounding galaxies, but the origin and meaning of the
Lambda CDM term has so far eluded scientists. The source of the
Lambda CDM, as well as all Dark Matter and Dark Energy in the
universe, can now be found in the new Newtonian term. Lambda
Beichler: The point of unification Vol. 10 10
CDM is a product of the point geometry in the modified Newton
gravity equation. Furthermore, the equation can be stated more
clearly by changing the new four-dimensional Einstein equation
(12)
to a five-dimensional form. Our normally experienced reality is
just a space-time projection of the five-dimensional space-time
tensor.
(13)
In this last formulation, the five-dimensional Γ tensor has two
parts, one symmetric and the other non-symmetric. The symmet-
ric part represents the metric curvature and projects to Gik in
normal space-time, while the non-symmetric portion represents
the new point geometry contribution of Dark Matter and Dark
Energy in normal space-time.
6. Conclusion
In some respects the single field and five-dimensional space-
time are mathematically and perhaps even physically indistin-
guishable, which begs the question whether or not they are in-
separable. They are not, however, inseparable because a primary
difference between the two does in fact exist and it can be speci-
fied. This difference rests in the simple fact that the single field
varies in density from one position in the fourth direction of
space, but the density clumps (particles) and variations are ap-
portioned (by Planck’s constant h) and relative (by the speed of
light c) to both the quantization and geometry of our normally
experienced four-dimensional space in the overall five-
dimensional space-time. Normal space-time is essentially the
collection of dimensionless points from which it is constructed.
The material extensions in normal space-time that we call ele-
mentary particles are thus arbitrary (in the sense that the origi-
nal creation of elementary particles occurred at random posi-
tions throughout the full extension of three-dimensional space)
and limited by the quantized geometry of five-dimensional
space-time.
However, these extended material bodies are given meaning,
relevance and limit by the single field which occupies the whole
extent of space-time as characterized by the quantum (h), elec-
tric permittivity (εo) and magnetic permeability (μo). In other
words, elementary particles are governed in their most basic
interactions as well as their original evolution (creation) by the
two physical constraint constants – Planck’s constant (h) and the
speed of light (c = (μoεo)-½). Planck’s constant is a property of the
space-time continuum while the speed of light is a property of
the single field that fills the space-time continuum. They com-
bine together to yield our physical and material reality. The
permittivity εo is the binding constant for the three-dimensions
of normal space, the permeability μo is the binding constant of
normal three-dimensional space to the fourth dimension of
space – they are the constants that characterize the single field –
and Planck’s constant is the binding constant of four-
dimensional space to time.
7. References
[1] Riemann, Bernhard. (1854, 1873). “On the Hypotheses which
lie at the Bases of Geometry.” Nature 8; 14-17, 36, 37.
[2] Gödel, Kurt. (1931) Monatshefte für Mathematik und Physik 38:
173-98.
[3] Clifford, William Kingdon. (1873) “Postulates of the Science of
Space”, Contemporary Review, (1874): 360-376; Reprinted in
Lectures and Essays, London: Macmillan. Volume 1: 295-323.
[4] Clifford, William Kingdon. (1873) “Preliminary Sketch of
Biquaternions”, Proceedings of the London Mathematical Society
(12 June 1873): 381-395; Reprinted in Mathematical Papers: 181-
200.
[5] Clifford, William Kingdon. (1882) Mathematical Papers. New
York: Chelsea Publishing, 1968.
[6] Clifford, William Kingdon (1870) Transactions of the Cambridge
Philosophical Society, 2 (1866/1876): 157-158; Reprinted in
Mathematical Papers: 21-22.
[7] Klein, Felix. (1890) Nicht-Euklidische Geometrie.
[8] Cartan, Élie. (1922) C. R. Acad. Sci. (Paris) 174:593–595.
[9] Cartan, Élie. Ann. Éc. Norm. 40: 325–412 and 41: 1–25; 42: 17–
88; (1926); Acta Math. 48: 1–42.
[10] Einstein, Albert. (1929) Observatory 51: 82-87; Sitzsber Preuss
Akad Wissen 1: 2-7; And (1930) Mathematische Annalen 102:
685-697.
[11] Beichler, James. (2006) “Alternative Physical Models of the
Universe.” In Life and Mind. Victoria: Trafford: 239-262.
Online at www.neurocosmology.net/sci%20revolutions.html.
[12] Heaviside, Oliver. (1893) “A gravitational and electromag-
netic analogy.” The Electrician 31: 81-82.
[13] Kaluza, Theodor. (1921) Sitzungsberichte der Preussischen
Akademie der Wissenschaften 54: 966-972.
[14] Klein, Oskar. (1926) Zeitschrift fur Physik 37, 12: 895-906; Na-
ture 118: 516; (1927) Zeitschrift fur Physik 46, 188-208.
[15] Einstein, A. and P. Bergmann. (1938 Annals of Mathematics 39,
3: 693-701.
[16] Einstein, A., P.G. Bergmann and Valentine Bargmann. (1941)
Theodor von Karman Anniversary Volume. Pasadena: Cal. Tech.:
212-225.
[17] Einstein, A. (1915) Berliner Sitzungsberichte (part 2): 844–847.
[18] Einstein, A. (1945) Annals of Mathematics 46, 4: 578-84.
[19] Einstein, A. (1956) Meaning of Relativity, 6th Edition. Calcutta:
Oxford and IBH Publishing.
[20] Hilbert, D., Lothar Nordheim, and J. von Neumann. (1927)
Mathematische Annalen 98: 1–30, doi:10.1007/BF01451579
[21] Brody, Dorje and Lane P. Hughston. (1999) Online at
arxiv.org/pdf/quant-ph/9906086v2.pdf.
[22] Hilbert, D. (1915) Göttinger Nachrichten: 395-407.
[23] Beichler, James. (1996) “Bubble, Bubble, Toil, and Trouble!”
Online at http://www.neurocosmology.net/yggdrasil.html.
[24] Beichler, James. (2010) "The Physical Origins of Dark Matter
and Dark Energy". In Ether Space-Time and Cosmology, 3, Physi-
cal vacuum, relativity and quantum physics. Apeiron. Online at
http://www.neurocosmology.net/5-d%20cosmology.html.
[25] Beichler, James. (2013) Four Pillars of Wisdom. An ebook to be
published.
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